CN112454200B - Multi-station machining device for manufacturing pressure sensor - Google Patents

Abstract

The invention belongs to the field of pressure sensor processing equipment, in particular to a multi-station processing device for manufacturing a pressure sensor, which aims at solving the problems that the existing processing equipment is poor in applicability, inconvenient to adjust a processing position, single in station, low in processing efficiency, incapable of fixing the position of the pressure sensor during processing and poor in stability. The processing equipment has the advantages of reasonable structure, convenience in operation, better applicability, convenience in adjusting the processing position, capability of performing multi-station processing on a processing table, higher processing efficiency, capability of fixing the position of the pressure sensor during processing and better stability.

Description

Multi-station machining device for manufacturing pressure sensor

Technical Field

The invention relates to the technical field of pressure sensor processing equipment, in particular to a multi-station processing device for manufacturing a pressure sensor.

Background

The pressure sensor is the most commonly used sensor in industrial practice, and is the most commonly used sensor in industrial practice, generally, the output of the common pressure sensor is an analog signal, the analog signal refers to that information parameters are represented as continuous signals in a given range, or within a continuous time interval, characteristic quantity representing the information can be represented as signals of any numerical value at any moment, and the commonly used pressure sensor is mainly manufactured by utilizing a piezoelectric effect, the sensor is also called as a piezoelectric sensor, and the pressure sensor is required to be produced by a processing device in the manufacturing and processing process;

however, the existing processing equipment is poor in applicability, inconvenient to adjust the processing position, single in station, low in processing efficiency, incapable of fixing the position of the pressure sensor during processing and poor in stability.

Disclosure of Invention

The invention aims to solve the defects in the prior art and provides a multi-station processing device for manufacturing a pressure sensor.

In order to achieve the purpose, the invention adopts the following technical scheme:

a multi-station processing device for manufacturing pressure sensors comprises a processing table, wherein a plurality of through holes are formed in the top of the processing table, fixing seats are fixedly arranged in the through holes, moving grooves are formed in the tops of the fixing seats, moving columns are slidably arranged in the moving grooves, first thread grooves are formed in the bottoms of the moving columns, rotating holes are formed in the inner walls of the bottoms of the moving grooves, lead screws are rotatably arranged in the rotating holes, the lead screws are arranged in the corresponding first thread grooves in a threaded manner, control sleeves are movably arranged at the bottoms of the lead screws and are slidably arranged on the corresponding fixing seats, station tables are arranged at the tops of the moving columns, pressure sensors are placed at the tops of the station tables, rotating grooves are formed in the bottoms of the station tables, fixing disks are fixedly arranged at the tops of the moving columns, the fixed disc is rotatably arranged in the corresponding rotary groove, two control holes are formed in the top of the station platform, second racks are respectively and slidably arranged in the two control holes, the top ends of the two second racks are respectively contacted with the bottom of the pressure sensor, anti-falling sheets are respectively and fixedly arranged at the bottoms of the two second racks, pressure springs are respectively sleeved on the two second racks, fixing holes are respectively formed in the inner wall of one side of each of the two control holes, connecting rods are respectively and slidably arranged in the two fixing holes, second thread grooves are respectively formed in the ends, close to each other, of the two connecting rods, second gears are respectively and rotatably arranged in the two control holes, the second gears are meshed with the corresponding second racks, screw rods are respectively and fixedly arranged on one sides of the two second gears, the screw rods are in the corresponding second thread grooves in a threaded manner, control plates are respectively and fixedly arranged at the ends, far away from each other, of the two connecting rods, and connecting frames are respectively and fixedly arranged on the sides, far away from each other side of the two control plates, the locating plates are fixedly mounted on one sides, close to each other, of the two connecting frames, and the two locating plates are respectively in contact with the two sides of the pressure sensor.

Preferably, the inner wall of the fixed hole is provided with a sliding groove, the connecting rod is fixedly provided with a sliding block, the sliding block is slidably arranged in the sliding groove, the connecting rod is driven to slide in the sliding groove when moving, and the position of the connecting rod when moving can be stabilized.

Preferably, an auxiliary groove is formed in the inner wall of the control hole, an auxiliary block is fixedly mounted on one side of the second gear, and the auxiliary block is rotatably mounted in the auxiliary groove.

Preferably, a plurality of slots have been seted up on the fixed disk, set up the spring groove that two symmetries set up on the inner wall in swivelling chute, equal slidable mounting has the inserted bar in two spring grooves, and the inserted bar is installed in the slot that corresponds.

Preferably, the equal fixed mounting in one end of two inserted bars has first spring, and the one end fixed mounting of first spring has seted up fixed chamber on the station bench on the inner wall in the spring groove that corresponds, has seted up two connecting holes on the bottom inner wall in fixed chamber, and equal slidable mounting has the connecting plate in two connecting holes, has seted up on the inner wall in spring groove and has removed the hole, and fixed mounting has the handle on the inserted bar, and handle slidable mounting is in removing the hole.

Preferably, one end of each connecting plate is fixedly mounted on the corresponding inserted rod, a first rack is fixedly mounted at one end, close to each other, of each connecting plate, a first gear is rotatably mounted in the corresponding fixed cavity, the two first racks are meshed with the first gear, the connecting plates drive the first racks to move, and the first racks drive the first gears to rotate.

Preferably, equal slidable mounting has the slider on the both sides inner wall of control sleeve, and the spout has all been seted up to the both sides of fixing base, and slider slidable mounting has the second spring in the spout that corresponds, the one end fixed mounting of slider, and the one end fixed connection of second spring is on the inner wall of the spout that corresponds, and the control sleeve removes and drives stopper roll-off spacing groove on the fixing base, can cancel the fixed restriction of control sleeve.

Preferably, the inner wall of the control sleeve is fixedly provided with a limiting block, the bottom of the fixing seat is provided with a plurality of limiting grooves, and the limiting block is arranged in the limiting grooves.

Compared with the prior art, the invention has the beneficial effects that:

the scheme is that the pressure sensor is placed on the station platform, the pressure sensor extrudes two second racks, the second racks pull corresponding pressure springs, the second racks drive corresponding second gear wheels to rotate, the screw rods drive corresponding connecting rods to move, the control panel drives corresponding connecting frames to move, the two positioning plates move in the directions close to each other, the two positioning plates stably clamp the pressure sensor, the handle is pulled to drive the inserting rods to move, the connecting plate drives the first racks to move, the first gear drives the other first rack to move, the connecting plate drives the corresponding inserting rods to move, the inserting rods slide out of the inserting grooves, the fixed limit of the station platform on the fixed disk can be cancelled, the station platform can be rotated, the control sleeve can be pulled to cancel the fixed limit of the control sleeve, the control sleeve rotates, the control sleeve drives the screw rods to rotate, and the screw rods drive the movable columns to move, the moving column drives the station platform to move, so that the use height of the station platform can be adjusted;

the multi-station processing device is reasonable in structure, convenient to operate, good in applicability, convenient to adjust the processing position, capable of performing multi-station processing on a processing table, high in processing efficiency, capable of fixing the position of the pressure sensor during processing and good in stability.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the drawings without creative efforts.

FIG. 1 is a schematic view of a front view structure according to the present invention;

FIG. 2 is a schematic view of part A of the structure proposed by the present invention;

FIG. 3 is a schematic structural diagram of part B according to the present invention;

FIG. 4 is a schematic structural diagram of part C according to the present invention;

fig. 5 is a schematic structural diagram of the connecting rod, the second rack, the screw and the second gear according to the present invention.

In the figure: 1. a processing table; 2. a fixed seat; 3. moving the column; 4. a screw rod; 5. a moving groove; 6. a control sleeve; 7. a station platform; 8. a pressure sensor; 9. a first gear; 10. a first rack; 11. a fixed cavity; 12. a connecting plate; 13. a first spring; 14. inserting a rod; 15. a slot; 16. a fixing hole; 17. a connecting rod; 18. a control panel; 19. a connecting frame; 20. positioning a plate; 21. a second rack; 22. a screw; 23. a second gear; 24. a pressure spring; 25. a slider; 26. a second spring; 27. a limiting groove; 28. and a limiting block.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1-5, a multi-station processing device for manufacturing a pressure sensor comprises a processing table 1, wherein a plurality of through holes are formed in the top of the processing table 1, fixed seats 2 are fixedly arranged in the through holes, moving grooves 5 are formed in the tops of the fixed seats 2, moving columns 3 are slidably arranged in the moving grooves 5, first thread grooves are formed in the bottoms of the moving columns 3, rotating holes are formed in the inner walls of the bottoms of the moving grooves 5, screw rods 4 are rotatably arranged in the rotating holes, the screw rods 4 are threadedly arranged in the corresponding first thread grooves, control sleeves 6 are movably arranged at the bottoms of the screw rods 4, the control sleeves 6 are slidably arranged on the corresponding fixed seats 2, station platforms 7 are arranged at the tops of the moving columns 3, pressure sensors 8 are arranged at the tops of the station platforms 7, rotating grooves are formed in the bottoms of the station platforms 7, the top ends of the plurality of moving columns 3 are fixedly provided with fixed disks which are rotatably arranged in corresponding rotating grooves, the top of the station platform 7 is provided with two control holes, the two control holes are internally and slidably provided with second racks 21, the top ends of the two second racks 21 are contacted with the bottoms of the pressure sensors 8, the bottoms of the two second racks 21 are respectively and fixedly provided with anti-falling sheets, the two second racks 21 are respectively sleeved with a pressure spring 24, the inner wall of one side of each of the two control holes is provided with a fixed hole 16, the two fixed holes 16 are respectively and slidably provided with a connecting rod 17, one ends of the two connecting rods 17, which are close to each other, are respectively provided with a second thread groove, the two control holes are internally and rotatably provided with second gears 23, the second gears 23 are meshed with the corresponding second racks 21, one sides of the two second gears 23 are respectively and fixedly provided with screw rods 22, the screw rods 22 are threadedly arranged in the corresponding second thread grooves, the equal fixed mounting in one end that two connecting rods 17 kept away from each other has control panel 18, and the equal fixed mounting in one side that two control panels 18 kept away from each other has link 19, and the equal fixed mounting in one side that two link 19 are close to each other has locating plate 20, and two locating plates 20 contact with pressure sensor 8's both sides respectively.

In this embodiment, the sliding tray has been seted up on the inner wall of fixed orifices 16, and fixed mounting has the sliding block on connecting rod 17, and sliding block slidable mounting drives the sliding block and slides in the sliding tray when connecting rod 17 removes in the sliding tray, can stabilize the position when connecting rod 17 removes. The connecting rod 17 is made of carbon fiber material, and has good rigidity and flexibility, so that the connecting rod can drive the sliding block to slide in the sliding groove in a soft degree.

In this embodiment, an auxiliary groove is formed in the inner wall of the control hole, an auxiliary block is fixedly mounted on one side of the second gear 23, and the auxiliary block is rotatably mounted in the auxiliary groove.

In this embodiment, a plurality of slots 15 have been seted up on the fixed disk, set up the spring groove that two symmetries set up on the inner wall in swivelling chute, and equal slidable mounting has inserted bar 14 in two spring grooves, and inserted bar 14 is installed in the slot 15 that corresponds.

In this embodiment, the equal fixed mounting in one end of two inserted bars 14 has first spring 13, and the one end fixed mounting of first spring 13 has seted up fixed chamber 11 on station platform 7 on the inner wall in the spring groove that corresponds, has seted up two connecting holes on the bottom inner wall in fixed chamber 11, and equal slidable mounting has connecting plate 12 in two connecting holes, has seted up on the inner wall in spring groove and has removed the hole, and fixed mounting has the handle on the inserted bar 14, and handle slidable mounting is in removing the hole.

In this embodiment, one end fixed mounting of connecting plate 12 is on the inserted bar 14 that corresponds, and the equal fixed mounting of one end that two connecting plates 12 are close to each other has first rack 10, and first gear 9 is installed to the internal rotation of fixed chamber 11, and two first racks 10 all mesh with first gear 9, and connecting plate 12 drives first rack 10 and removes, and first rack 10 drives first gear 9 and rotates.

In this embodiment, equal slidable mounting has slider 25 on the both sides inner wall of control sleeve 6, and the spout has all been seted up to the both sides of fixing base 2, and slider 25 slidable mounting is in the spout that corresponds, and the one end fixed mounting of slider 25 has second spring 26, and the one end fixed connection of second spring 26 is on the inner wall of the spout that corresponds, and control sleeve 6 removes and drives stopper 28 roll-off spacing groove 27 on fixing base 2, can cancel the fixed restriction of control sleeve 6.

In this embodiment, fixed mounting has stopper 28 on the inner wall of control sleeve 6, and a plurality of spacing grooves 27 have been seted up to the bottom of fixing base 2, and stopper 28 installs in spacing groove 27.

In this embodiment, by placing the pressure sensor 8 on the station table 7, the pressure sensor 8 extrudes two second racks 21, the two second racks 21 move, so that the second racks 21 pull corresponding pressure springs 24, the pressure springs 24 elastically deform, the second racks 21 drive corresponding second gears 23 to rotate, the second gears 23 drive corresponding screws 22 to rotate, so that the screws 22 drive corresponding connecting rods 17 to move, the connecting rods 17 drive corresponding control plates 18 to move, the control plates 18 drive corresponding connecting frames 19 to move, the connecting frames 19 drive corresponding positioning plates 20 to move, the two positioning plates 20 move in directions close to each other, so that the two positioning plates 20 stably clamp the pressure sensor 8, the pressure sensor 8 can be processed, the handle is pulled, so that the handle drives the inserted rod 14 to move, and the inserted rod 14 can drive the connecting plate 12 to move, the connecting plate 12 drives the first rack 10 to move, the first rack 10 drives the first gear 9 to rotate, so that the first gear 9 drives another first rack 10 to move, the first rack 10 drives the corresponding connecting plate 12 to move, the connecting plate 12 drives the corresponding inserted rod 14 to move, the inserted rod 14 slides out of the slot 15, the fixed limit of the station table 7 on the fixed disk can be cancelled, the station table 7 can be rotated, the use position of the station table 7 can be adjusted, the control sleeve 6 is pulled, the control sleeve 6 moves on the fixed seat 2 and drives the limit block 28 to slide out of the limit slot 27, the fixed limit of the control sleeve 6 can be cancelled, the control sleeve 6 is rotated, the control sleeve 6 drives the lead screw 4 to rotate, the lead screw 4 drives the movable column 3 to move, the movable column 3 drives the station table 7 to move, and the use height of the station table 7 can be adjusted.

Compared with the prior art, the invention has the technical progress that: the multi-station processing device is reasonable in structure, convenient to operate, good in applicability, convenient to adjust the processing position, high in processing efficiency, capable of fixing the position of the pressure sensor 8 during processing and good in stability, and multi-station processing can be performed on the processing table 1.

The scheme is that the pressure sensor is placed on the station platform, the pressure sensor extrudes two second racks, the second racks pull corresponding pressure springs, the second racks drive corresponding second gear wheels to rotate, the screw rods drive corresponding connecting rods to move, the control panel drives corresponding connecting frames to move, the two positioning plates move in the directions close to each other, the two positioning plates stably clamp the pressure sensor, the handle is pulled to drive the inserting rods to move, the connecting plate drives the first racks to move, the first gear drives the other first rack to move, the connecting plate drives the corresponding inserting rods to move, the inserting rods slide out of the inserting grooves, the fixed limit of the station platform on the fixed disk can be cancelled, the station platform can be rotated, the control sleeve can be pulled to cancel the fixed limit of the control sleeve, the control sleeve rotates, the control sleeve drives the screw rods to rotate, and the screw rods drive the movable columns to move, the moving column drives the station platform to move, so that the use height of the station platform can be adjusted;

the multi-station processing device is reasonable in structure, convenient to operate, good in applicability, convenient to adjust the processing position, capable of performing multi-station processing on a processing table, high in processing efficiency, capable of fixing the position of the pressure sensor during processing and good in stability.

The embodiments are described in detail, and the principle and the embodiments of the present invention should be described herein by using specific embodiments, and the description of the embodiments is only used to help understand the method and the core idea of the present invention; meanwhile, for a person skilled in the art, according to the idea of the present invention, there may be variations in the specific embodiments and the application scope, and in summary, the content of the present specification should not be construed as a limitation to the present invention.

Claims (8)

1. A multi-station processing device for manufacturing a pressure sensor comprises a processing table (1) and is characterized in that a plurality of through holes are formed in the top of the processing table (1), fixing seats (2) are fixedly mounted in the through holes, moving grooves (5) are formed in the tops of the fixing seats (2), moving columns (3) are slidably mounted in the moving grooves (5), first thread grooves are formed in the bottoms of the moving columns (3), rotating holes are formed in the inner walls of the bottoms of the moving grooves (5), lead screws (4) are rotatably mounted in the rotating holes, the lead screws (4) are threadedly mounted in the corresponding first thread grooves, control sleeves (6) are movably mounted at the bottoms of the lead screws (4), the control sleeves (6) are slidably mounted on the corresponding fixing seats (2), and station tables (7) are arranged at the tops of the moving columns (3), pressure sensors (8) are placed at the tops of the station platforms (7), rotating grooves are formed in the bottoms of the station platforms (7), fixed disks are fixedly installed at the top ends of the moving columns (3), the fixed disks are rotatably installed in the corresponding rotating grooves, two control holes are formed in the tops of the station platforms (7), second racks (21) are slidably installed in the two control holes, the top ends of the second racks (21) are in contact with the bottoms of the pressure sensors (8), anti-falling sheets are fixedly installed at the bottoms of the second racks (21), pressure springs (24) are sleeved on the second racks (21), fixing holes (16) are formed in the inner wall of one side of each control hole, connecting rods (17) are slidably installed in the two fixing holes (16), and second thread grooves are formed in the ends, close to each other, of the two connecting rods (17), all rotate in two control holes and install second gear (23), second gear (23) and second rack (21) meshing that corresponds, the equal fixed mounting in one side of two second gear (23) has screw rod (22), screw rod (22) screw thread is installed in the second thread groove that corresponds, the equal fixed mounting in one side of keeping away from each other of two connecting rod (17) has control panel (18), the equal fixed mounting in one side of keeping away from each other of two control panel (18) has link (19), the equal fixed mounting in one side that two link (19) are close to each other has locating plate (20), two locating plate (20) contact with the both sides of pressure sensor (8) respectively.

2. The multi-station processing device for manufacturing the pressure sensor as claimed in claim 1, wherein a sliding groove is formed on the inner wall of the fixing hole (16), a sliding block is fixedly mounted on the connecting rod (17), and the sliding block is slidably mounted in the sliding groove.

3. The multistation processing device for manufacturing the pressure sensor according to claim 1, characterized in that an auxiliary groove is formed in the inner wall of the control hole, an auxiliary block is fixedly mounted on one side of the second gear (23), and the auxiliary block is rotatably mounted in the auxiliary groove.

4. The multistation processing device for manufacturing the pressure sensor according to claim 1, characterized in that a plurality of slots (15) are formed in the fixed disc, two symmetrically-arranged spring slots are formed in the inner wall of the rotating slot, the two spring slots are respectively and slidably provided with the inserting rod (14), and the inserting rods (14) are arranged in the corresponding slots (15).

5. The multi-station machining device for manufacturing the pressure sensor according to claim 4, wherein one end of each of the two insertion rods (14) is fixedly provided with a first spring (13), one end of each first spring (13) is fixedly arranged on the inner wall of the corresponding spring groove, the station table (7) is provided with a fixed cavity (11), the inner wall of the bottom of each fixed cavity (11) is provided with two connecting holes, the two connecting holes are respectively and slidably provided with a connecting plate (12), the inner wall of each spring groove is provided with a moving hole, the insertion rods (14) are fixedly provided with handles, and the handles are slidably arranged in the moving holes.

6. The multistation machining device for manufacturing the pressure sensor is characterized in that one end of each connecting plate (12) is fixedly installed on the corresponding inserted rod (14), one end, close to each other, of each connecting plate (12) is fixedly provided with a first rack (10), a first gear (9) is rotatably installed in each fixing cavity (11), and the two first racks (10) are meshed with the first gear (9).

7. The multistation processing device for manufacturing the pressure sensor according to claim 1, characterized in that sliding blocks (25) are slidably mounted on the inner walls of two sides of the control sleeve (6), sliding grooves are formed in two sides of the fixing seat (2), the sliding blocks (25) are slidably mounted in the corresponding sliding grooves, a second spring (26) is fixedly mounted at one end of each sliding block (25), and one end of each second spring (26) is fixedly connected to the inner wall of the corresponding sliding groove.

8. The multistation processing device for manufacturing the pressure sensor according to claim 1 is characterized in that a limiting block (28) is fixedly mounted on the inner wall of the control sleeve (6), a plurality of limiting grooves (27) are formed in the bottom of the fixing seat (2), and the limiting block (28) is mounted in the limiting grooves (27).

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